Genetic interaction of DED1 encoding a putative ATP-dependent RNA helicase with SRM1 encoding a mammalian RCC1 homolog in Saccharomyces cerevisiae

 The Saccharomyces cerevisiae temperature-sensitive mutants srm1-1, mtr1-2 and prp20-1 carry alleles of a gene encoding a homolog of mammalian RCC1. In order to identify a protein interacting with RCC1, a series of suppressors of the srm1-1 mutation were isolated as cold-sensitive mutants and one of the mutants, designated ded1-21, was found to be defective in the DED1 gene. The double mutant, srm1-1 ded1-21, could grow at 35° C, but not at 37° C. A revertant of srm1-1 ded1-21 that became able to grow at 37° C acquired another mutation in the SRM1 gene, indicating the tight relationship between SRM1 and DED1. In all the rcc1 ^- strains examined, the amount of mutated SRM1 proteins was reduced or not detectable at the nonpermissive temperature. While mutated SRM1 protein was stabilized in all of the rcc1 ^- strains by the ded1-21 mutation, the ded1-21 mutation suppressed both srm1-1 and mtr1-2, but not the prp20-1 mutation, contrary to the previous finding that overproduction of the S. cerevisiae Ran homolog GSP1 suppresses prp20-1, but not srm1-1 or mtr1-2. Received: 20 March 1996/Accepted: 1 July 1996     

RanBP1, a Ras-like nuclear G protein binding to Ran/TC4, inhibits RCC1 via Ran/TC4

A human protein that is 92% identical and 97% homologous at the amino acid level to RanBP1 from mouse was identified by the two-hybrid method, using two types of target cDNAs fused to sequences encoding the GAL4 DNA-binding domain. The target cDNAs encoded the human Ran/TC4 and human RCC1 proteins, respectively. An in vitro binding experiment showed that RanBP1 binds to RCC1 with the aid of Ran. Partially purified, GST-fused RanBP1 inhibited RCC1-stimulated guanine nucleotide release from Ran in vitro. Consistent with this in vitro finding, overproduction of human RanBP1 was detrimental to growth of tsBN2, a temperature-sensitive BHK21 hamster cell line defective in the RCC1 gene, and inhibited the growth of the Saccharomyces cerevisiae rcc1 mutants prp20, mtr1 and srm1. The specific effect of RanBP1 on rcc1 ^– cells was confirmed by the finding that overproduction of RanBP1 induces significant levels of expression of a FUS1-lacZ gene and an increase in mating efficiencies in a ste3, pheromone receptor-deficient yeast mutant. This phenotype is similar to the srm1, a mutant isolated as a suppressor that restores mating to receptorless mutants. These findings indicate that RanBP1 negatively regulates RCC1.     

Regulation of RNA processing and transport by a nuclear guanine nucleotide release protein and members of the Ras superfamily.

The RCC1 gene of mammals encodes a guanine nucleotide release protein (GNRP). RCC1 and a homolog in Saccharomyces cerevisiae (MTR1/PRP20/SRM1) have previously been implicated in control of mRNA metabolism and export from the nucleus. We here demonstrate that a temperature-sensitive fission yeast mutant which has a mutation in a homologous gene, and two of three additional (mtr1/prp20/srm1) mutants accumulate nuclear poly(A)+ RNA at 37 degrees C. In S.cerevisiae, maturation of rRNA and tRNA is also inhibited at 37 degrees C. Nevertheless, studies with the corresponding BHK-21 cell mutant indicate that protein import into the nucleus continues. MTR1 homologs regulate RNA processing at a point which is distinct from their regulation of chromosome condensation since: (i) poly(A)+ RNA accumulation in the fission yeast mutant precedes chromosome condensation, and (ii) unlike chromosome condensation, accumulation of nuclear poly(A)+ RNA does not require p34cdc28 kinase activation or protein synthesis. Moreover, experiments involving inhibition of DNA synthesis indicate that the S.cerevisiae homolog does not govern cell cycle checkpoint control. Since RCC1p acts as GNRP for Ran, a small nuclear GTPase of the ras superfamily, we have identified two homologs of Ran in S.cerevisiae (CNR1 and CNR2). Only CNR1 is essential, but both code for proteins extremely similar to Ran and can suppress mtr1 mutations in allele-specific fashion. Thus, MTR1 and its homologs appear to act as GNRPs for a family of conserved GTPases in controlling RNA metabolism and transport. Their role in governing checkpoint control appears to be restricted to higher eukaryotes.     

Mutation of the hamster cell cycle gene RCC1 is complemented by the homologous genes of Drosophila and S.cerevisiae.

The RCC1 gene has been isolated from several vertebrates, including human, hamster and Xenopus. Genes similar to RCC1, namely BJ1 and SRM1/PRP20, have been isolated from the insect Drosophila and from the budding yeast Saccharomyces cerevisiae. A mutation of the RCC1 gene in the hamster BHK21 cell line, tsBN2, confers pleiotropic phenotypes, including G1 arrest and premature induction of mitosis in cells synchronized at the G1/S boundary. Similarly, mutations of the SRM1/PRP20 gene are pleiotropic; the srm1 mutant shows G1 arrest and suppression of the mating defect of mutants lacking pheromone receptors, and the prp20 mutant shows an alteration in mRNA metabolism. Here we show that both BJ1 and SRM1/PRP20 complement the temperature sensitive phenotype of the tsBN2 cells. Like RCC1 proteins of vertebrates, the protein products of the Drosophila and yeast RCC1 homologues were located in the nuclei of the mammalian cells. These results suggest that the BJ1 and SRM1/PRP20 genes are functionally equivalent to the vertebrate RCC1 genes, and that the RCC1 gene plays an important role in the regulation of gene expression in the eukaryotic cell cycle.     

Participation of <Emphasis Type="Italic">SRM5/CDC28</Emphasis>, <Emphasis Type="Italic">SRM8/NET1</Emphasis>, and <Emphasis Type="Italic">SRM12/HFI1</Emphasis> genes in checkpoint control in yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

About twenty genes participating in checkpoint control are known in yeast Saccharomyces cerevisiae. The involvement of SRM genes in the cell cycle arrest under the action of DNA damaging agents was studied in this work. These genes were earlier defined as genes affecting genetic stability and radiosensitivity. It was shown that mutations srm5/cdc28-srm, srm8/net1-srm, and srm12/hfi1-srm fail the cell cycle arrest in the presence of DNA damage and influence the checkpoint arrest in G0/S (srm5, srm8), G1/S (srm5, srm8, srm12), S (srm5, srm12), and G₂/M (srm5). It seems likely that genes SRM5/CDC28, SRM12/HFI1/ADA1, and SRM8/NET1 are involved in a cell response to DNA damage, and in checkpoint regulation in particular.     

A suppressor of yeast spp81/ded1 mutations encodes a very similar putative ATP-dependent RNA helicase

The spp81/ded1 mutations were isolated as suppressors of a Saccharomyces cerevisiae pre-mRNA splicing mutation, prp8-1. The SPP81/DED1 gene encodes a putative ATP-dependent RNA helicase. While attempting to clone the wild-type SPP81/DED1 gene we isolated plasmids which were able to suppress the cold-sensitive growth defect of spp81 mutants. These plasmids encoded a gene (named DBP1) which mapped to chromosome XVI and not to the SPP81/DED1 locus on chromosome XV. The cloned gene suppressed the defect of spp81/ded1 mutants when present on both high and low copy-number plasmids but complemented spp81/ded1 null mutants only when present on high copy-number plasmids. In contrast to the SPP81/DED1 gene the DBP1 gene was not essential for cell viability. The nucleotide sequence of the DBP1 gene revealed that it also encoded a putative ATP-dependent RNA helicase which showed considerable similarity at the amino acid level to the SPP81/DED1 protein.     

New Mutations of SRMGenes in Saccharomyces cerevisiae and Certain Characteristics of Their Phenotypic Effects

The effects of the previously identified mutations in nuclear genes SRM8, SRM12, SRM15, and SRM17on the maintenance of chromosomes and recombinant plasmids in Saccharomyces cerevisiaecells and on cell sensitivity to ionizing radiation were studied. The srm8mutation caused an increase in spontaneous chromosome loss in diploid cells. In yeast cells with the intact mitochondrial genome, all examined srmmutations decreased the mitotic stability of a centromeric recombinant plasmid with the chromosomal ARS element. Mutations srm12, srm15, and srm17also decreased the mitotic stability of a centromereless plasmid containing the same ARS element, whereas the srm8mutation did not markedly affect the maintenance of this plasmid. Mutations srm8, srm12, and srm17were shown to increase cell sensitivity to -rays. The SRM8gene was mapped, cloned, and found to correspond to the open reading frame YJLO76w in chromosome X.     

Synthetic Lethality of Yeast slt Mutations with U2 Small Nuclear RNA Mutations Suggests Functional Interactions between U2 and U5 snRNPs That Are Important for Both Steps of Pre-mRNA Splicing

A genetic screen was devised to identify Saccharomyces cerevisiae splicing factors that are important for the function of the 5′ end of U2 snRNA. Six slt (stands for synthetic lethality with U2) mutants were isolated on the basis of synthetic lethality with a U2 snRNA mutation that perturbs the U2-U6 snRNA helix II interaction. SLT11 encodes a new splicing factor and SLT22 encodes a new RNA-dependent ATPase RNA helicase (D. Xu, S. Nouraini, D. Field, S. J. Tang, and J. D. Friesen, Nature 381:709–713, 1996). The remaining four slt mutations are new alleles of previously identified splicing genes: slt15, previously identified as prp17 (slt15/prp17-100), slt16/smd3-1, slt17/slu7-100, and slt21/prp8-21. slt11-1 and slt22-1 are synthetically lethal with mutations in the 3′ end of U6 snRNA, a region that affects U2-U6 snRNA helix II; however, slt17/slu7-100 and slt21/prp8-21 are not. This difference suggests that the latter two factors are unlikely to be involved in interactions with U2-U6 snRNA helix II but rather are specific to interactions with U2 snRNA. Pairwise synthetic lethality was observed among slt11-1 (which affects the first step of splicing) and several second-step factors, including slt15/prp17-100, slt17/slu7-100, and prp16-1. Mutations in loop 1 of U5 snRNA, a region that is implicated in the alignment of the two exons, are synthetically lethal with slu4/prp17-2 and slu7-1 (D. Frank, B. Patterson, and C. Guthrie, Mol. Cell. Biol. 12:5179–5205, 1992), as well as with slt11-1, slt15/prp17-100, slt17/slu7-100, and slt21/prp8-21. These same U5 snRNA mutations also interact genetically with certain U2 snRNA mutations that lie in the helix I and helix II regions of the U2-U6 snRNA structure. Our results suggest interactions among U2 snRNA, U5 snRNA, and Slt protein factors that may be responsible for coupling and coordination of the two reactions of pre-mRNA splicing.     

An extragenic suppressor ofprp24-1 defines genetic interaction betweenPRP24 andPRP21 gene products ofSaccharomyces cerevisiae

The temperature-sensitiveprp24-1 mutation defines a gene product required for the first step in pre-mRNA splicing. PRP24 is probably a component of the U6 snRNP particle. We have applied genetic reversion analysis to identify proteins that interact with PRP24. Spontaneous revertants of the temperaturesensitive (ts)prp24-1 phenotype were analyzed for those that are due to extragenic suppression. We then extended our analysis to screen for suppressors that confer a distinct conditional phenotype. We have identified a temperature-sensitive extragenic suppressor, which was shown by genetic complementation analysis to be allelic toprp21-1. This suppressor,prp21-2, accumulates pre-mRNA at the non-permissive temperature, a phenotype similar to that ofprp21-1. prp21-2 completely suppresses the splicing defect and restores in vivo levels of the U6 snRNA in theprp24-1 strain. Genetic analysis of the suppressor showed thatprp21-2 is not a bypass suppressor ofprp24-1. The suppression ofprp24-1 byprp21-2 is gene specific and also allele specific with respect to both the loci. Genetic interactions with other components of the pre-spliceosome have also been studied. Our results indicate an interaction between PRP21, a component of the U2 snRNP, and PRP24, a component of the U6 snRNP. These results substantiate other data showing U2–U6 snRNA interactions.     

The SRM12/ADA1 Gene Sequence Inserted into Recombinant Plasmids Makes Them More Mitotically Stable in Budding Yeast Cells

TheSRM12/ADA1 gene sequence inserted into a recombinant circular plasmid improves its maintenance in budding yeast (Saccharomyces cerevisiae) cells. Plasmid stabilization caused by the integrated SRM12 sequence does not require the SRM12 function complementing the srm12 mutation and depends on the orientation of the inserted sequence in the vector. This stabilization is mainly due to a decrease in spontaneous plasmid underreplication/copy loss rather than an increase in the fidelity of mitotic plasmid segregation.     

A Link between Secretion and Pre-mRNA Processing Defects in Saccharomyces cerevisiae and the Identification of a Novel Splicing Gene, RSE1

Secretory proteins in eukaryotic cells are transported to the cell surface via the endoplasmic reticulum (ER) and the Golgi apparatus by membrane-bounded vesicles. We screened a collection of temperature-sensitive mutants of Saccharomyces cerevisiae for defects in ER-to-Golgi transport. Two of the genes identified in this screen were PRP2, which encodes a known pre-mRNA splicing factor, and RSE1, a novel gene that we show to be important for pre-mRNA splicing. Both prp2-13 and rse1-1 mutants accumulate the ER forms of invertase and the vacuolar protease CPY at restrictive temperature. The secretion defect in each mutant can be suppressed by increasing the amount of SAR1, which encodes a small GTPase essential for COPII vesicle formation from the ER, or by deleting the intron from the SAR1 gene. These data indicate that a failure to splice SAR1 pre-mRNA is the specific cause of the secretion defects in prp2-13 and rse1-1. Moreover, these data imply that Sar1p is a limiting component of the ER-to-Golgi transport machinery and suggest a way that secretory pathway function might be coordinated with the amount of gene expression in a cell.     

The identification of a Caenorhabditis elegans homolog of p34cdc2 kinase

We have identified a Caenorhabditis elegans homolog of p34^cdc2 kinase. The C. elegans homolog, ncc-1, is ～-60% identical to p34^cdc2 of Homo sapiens. When expressed from a constitutive yeast promoter, ncc-1 is capable of complementing a conditional lethal mutation in the CDC28 gene of Saccharomyces cerevisiae, indicating that this C. elegans homolog can properly regulate the cell cycle.     

Isolation of novel pre-mRNA splicing mutants of Schizosaccharomyces pombe

New prp (pre-mRNA processing) mutants of the fission yeast Schizosaccharomyces pombe were isolated from a bank of 700 mutants that were either temperature sensitive (ts^-) or cold sensitive (cs^-) for growth. The bank was screened by Northern blot analysis with probes complementary to S. pombe U6 small nuclear RNA (sn RNA), the gene for which has a splicesomal (mRNA-type) intron. We identified 12 prp mutants that accumulated the U6 snRNA precursor at the nonpermissive temperature. All such mutants were also found to have defects in an early step of TFIID pre-mRNA splicing at the nonpermissive temperature. Complementation analyses showed that seven of the mutants belong to six new complementation groups designated as prp8 and prp10-prp14, whereas the five other mutants were classified into the known complementation groups prp1, prp2 and prp3. Interestingly, some of the isolated prp mutants produced elongated cells at the nonpermissive temperature, which is a phenotype typical of cell division cycle (cdc) mutants. Based on these findings, we propose that some of the wild-type products from these prp ⁺ genes play important roles in the cellular processes of pre-mRNA splicing and cell cycle progression.     

Involvement of the Spliceosomal U4 Small Nuclear RNA in Heterochromatic Gene Silencing at Fission Yeast Centromeres

prp13-1 is one of the mutants isolated in a screen for defective pre-mRNA splicing at a nonpermissive temperature in fission yeast Schizosaccharomyces pombe. We cloned the prp13⁺ gene and found that it encodes U4 small nuclear RNA (snRNA) involved in the assembly of the spliceosome. The prp13-1 mutant produced elongated cells, a phenotype similar to cell division cycle mutants, and displays a high incidence of lagging chromosomes on anaphase spindles. The mutant is hypersensitive to the microtubule-destabilizing drug thiabendazole, supporting that prp13-1 has a defect in chromosomal segregation. We found that the prp13-1 mutation resulted in expression of the ura4⁺ gene inserted in the pericentromeric heterochromatin region and reduced recruitment of the heterochromatin protein Swi6p to that region, indicating defects in the formation of pericentromeric heterochromatin, which is essential for the segregation of chromosomes, in prp13-1. The formation of centromeric heterochromatin is induced by the RNA interference (RNAi) system in S. pombe. In prp13-1, the processing of centromeric noncoding RNAs to siRNAs, which direct the heterochromatin formation, was impaired and unprocessed noncoding RNAs were accumulated. These results suggest that U4 snRNA is required for the RNAi-directed heterochromatic gene silencing at the centromeres. In relation to the linkage between the spliceosomal U4 snRNA and the RNAi-directed formation of heterochromatin, we identified a mRNA-type intron in the centromeric noncoding RNAs. We propose a model in which the assembly of the spliceosome or a sub-spliceosome complex on the intron-containing centromeric noncoding RNAs facilitates the RNAi-directed formation of heterochromatin at centromeres, through interaction with the RNA-directed RNA polymerase complex.     

An extragenic suppressor ofprp24-1 defines genetic interaction betweenPRP24 andPRP21 gene products ofSaccharomyces cerevisiae

The temperature-sensitiveprp24-1 mutation defines a gene product required for the first step in pre-mRNA splicing. PRP24 is probably a component of the U6 snRNP particle. We have applied genetic reversion analysis to identify proteins that interact with PRP24. Spontaneous revertants of the temperaturesensitive (ts)prp24-1 phenotype were analyzed for those that are due to extragenic suppression. We then extended our analysis to screen for suppressors that confer a distinct conditional phenotype. We have identified a temperature-sensitive extragenic suppressor, which was shown by genetic complementation analysis to be allelic toprp21-1. This suppressor,prp21-2, accumulates pre-mRNA at the non-permissive temperature, a phenotype similar to that ofprp21-1. prp21-2 completely suppresses the splicing defect and restores in vivo levels of the U6 snRNA in theprp24-1 strain. Genetic analysis of the suppressor showed thatprp21-2 is not a bypass suppressor ofprp24-1. The suppression ofprp24-1 byprp21-2 is gene specific and also allele specific with respect to both the loci. Genetic interactions with other components of the pre-spliceosome have also been studied. Our results indicate an interaction between PRP21, a component of the U2 snRNP, and PRP24, a component of the U6 snRNP. These results substantiate other data showing U2–U6 snRNA interactions.     

Prp21, a U2-snRNP-associated protein, and Prp24, a U6-snRNP-associated protein, functionally interact during spliceosome assembly in yeast

Earlier studies on genetic suppression ofprp24-1 byprp21-2 suggested an association between yeast Prp21 and Prp24 proteins, which are associated, respectively, with U2 snRNA and U6 snRNA. Here we report analyses of physical and functional interaction between these factors. Missense mutations in functionally important domains reside inprp21-2 andprp24-1. Two-hybrid assays do not detect interaction between wild-type or mutant proteins. Prp21-2 and Prp24-1 protein inprp21-2 orprp24-1 extracts can be heat-inactivatedin vitro. In contrast, heat-treated extracts from the revertant strainprp21-2 prp24-1 demonstrate allele-specific restoration of splicing. Suppression ofprp24-1 byprp21-2 does not cause coimmunoprecipitation of U2 and U6 snRNAs. We demonstrate the presence of Prp21 in the spliceosome assembly intermediate A2-1, and our data suggest the presence of Prp24 in the same complex. Kinetic analysis of assembly in heat-treated revertant extracts reveal a rate-limiting conversion of complex B to A2-1, suggesting transient association between the mutant proteins at this step. Our data also imply a requirement for Prp21 during B to A2-1 conversion. We conclude that a transient yet likely functional association between Prp21 and Prp24 occurs during spliceosome assembly.     

Rad21l1 cohesin subunit is dispensable for spermatogenesis but not oogenesis in zebrafish

During meiosis I, ring-shaped cohesin complexes play important roles in aiding the proper segregation of homologous chromosomes. RAD21L is a meiosis-specific vertebrate cohesin that is required for spermatogenesis in mice but is dispensable for oogenesis in young animals. The role of this cohesin in other vertebrate models has not been explored. Here, we tested if the zebrafish homolog Rad21l1 is required for meiotic chromosome dynamics during spermatogenesis and oogenesis. We found that Rad21l1 localizes to unsynapsed chromosome axes. It is also found between the axes of the mature tripartite synaptonemal complex (SC) in both sexes. We knocked out rad21l1 and found that nearly all rad21l1^-/- mutants develop as fertile males, suggesting that the mutation causes a defect in juvenile oogenesis, since insufficient oocyte production triggers female to male sex reversal in zebrafish. Sex reversal was partially suppressed by mutation of the checkpoint gene tp53, suggesting that the rad21l1 mutation activates Tp53-mediated apoptosis or arrest in females. This response, however, is not linked to a defect in repairing Spo11-induced double-strand breaks since deletion of spo11 does not suppress the sex reversal phenotype. Compared to tp53 single mutant controls, rad21l1^-/- tp53^-/- double mutant females produce poor quality eggs that often die or develop into malformed embryos. Overall, these results indicate that the absence of rad21l1^-/- females is due to a checkpoint-mediated response and highlight a role for a meiotic-specific cohesin subunit in oogenesis but not spermatogenesis.